Comparison of Iodide and Iodate Accumulation and Volatilization by Filamentous Fungi during Static Cultivation

Five common fungal strains, Cladosporium cladosporioides , Aspergillus clavatus , Penicillium citrinum , Fusarium oxysporum , and Alternaria alternata , were cultivated in presence of iodide and iodate to evaluate their efficiency in iodine biovolatilization and bioaccumulation. Our results suggest...

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Veröffentlicht in:	Water, air, and soil pollution air, and soil pollution, 2017-06, Vol.228 (6), p.1, Article 225
Hauptverfasser:	Duborská, Eva, Urík, Martin, Bujdos, Marek
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Sprache:	eng
Schlagworte:	Atmospheric Protection/Air Quality Control/Air Pollution Bioaccumulation Biogeochemistry Climate Change/Climate Change Impacts Comparative analysis Cultivation Destruction Disinfection & disinfectants Earth and Environmental Science Efficiency Environment Environmental monitoring Filamentous microorganisms Fungi Fungiculture Fusarium Fusarium oxysporum Hydrogeology Iodides Iodine Iodine compounds Microorganisms Ozone Ozone layer Ozonosphere Penicillium citrinum Soil Science & Conservation Volatilization Water Quality/Water Pollution
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creator	Duborská, Eva Urík, Martin Bujdos, Marek
description	Five common fungal strains, Cladosporium cladosporioides , Aspergillus clavatus , Penicillium citrinum , Fusarium oxysporum , and Alternaria alternata , were cultivated in presence of iodide and iodate to evaluate their efficiency in iodine biovolatilization and bioaccumulation. Our results suggest that iodide and iodate bioaccumulation by microscopic filamentous fungi is similar although the biological transformation into volatile iodine compounds is driven by various pathways resulting in higher volatilization efficiency of iodate. Thus, the mobilization of iodate by filamentous fungi is superior to iodide mobilization. Our paper is also the first to compare the iodide and iodate volatilization efficiency by microorganisms. Our results highlight the significant role of filamentous fungi in biogeochemistry of iodine, especially in formation of environmentally reactive volatile forms that may contribute to ozone layer destruction.
doi_str_mv	10.1007/s11270-017-3407-4
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Our results suggest that iodide and iodate bioaccumulation by microscopic filamentous fungi is similar although the biological transformation into volatile iodine compounds is driven by various pathways resulting in higher volatilization efficiency of iodate. Thus, the mobilization of iodate by filamentous fungi is superior to iodide mobilization. Our paper is also the first to compare the iodide and iodate volatilization efficiency by microorganisms. 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subjects	Atmospheric Protection/Air Quality Control/Air Pollution Bioaccumulation Biogeochemistry Climate Change/Climate Change Impacts Comparative analysis Cultivation Destruction Disinfection & disinfectants Earth and Environmental Science Efficiency Environment Environmental monitoring Filamentous microorganisms Fungi Fungiculture Fusarium Fusarium oxysporum Hydrogeology Iodides Iodine Iodine compounds Microorganisms Ozone Ozone layer Ozonosphere Penicillium citrinum Soil Science & Conservation Volatilization Water Quality/Water Pollution
title	Comparison of Iodide and Iodate Accumulation and Volatilization by Filamentous Fungi during Static Cultivation
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